RNA-based temperature sensing is common in bacteria that live in fluctuating environments. Most naturally-occurring RNA thermosensors are heat-inducible, have long sequences, and function by sequestering the ribosome binding site in a hairpin structure at lower temperatures. Here, we demonstrate the de novo design of short, heat-repressible RNA thermosensors. These thermosensors contain a cleavage site for RNase E, an enzyme native to Escherichia coli and many other organisms, in the 5′ untranslated region of the target gene. At low temperatures, the cleavage site is sequestered in a stem–loop, and gene expression is unobstructed. At high temperatures, the stem–loop unfolds, allowing for mRNA degradation and turning off expression. We demonstrated that these thermosensors respond specifically to temperature and provided experimental support for the central role of RNase E in the mechanism. We also demonstrated the modularity of these RNA thermosensors by constructing a three-input composite circuit that utilizes transcriptional, post-transcriptional, and post-translational regulation. A thorough analysis of the 24 thermosensors allowed for the development of design guidelines for systematic construction of similar thermosensors in future applications. These short, modular RNA thermosensors can be applied to the construction of complex genetic circuits, facilitating rational reprogramming of cellular processes for synthetic biology applications.
No information is available on transcription factors (TF), the main regulators of gene expression, in perinatal asphyxia (PA), and as pathomechanisms in PA are different, data on TFs from ischemia or hypoxia cannot be simply extrapolated to PA, and no studies have been reported to show an expressional pattern or the concerted action of TFs. We, therefore, used a gene-hunting technique, subtractive hybridization, to show sequences different in brains of normoxic and perinatally asphyxiated (10 and 20 min of asphyxia) rats. These subtracted sequences were identified by gene bank and assigned to individual genes. At 10 min of PA the TFs NFI/CAAT-binding protein, NF-kappa-B p65, N-myc, basic helix loop helix protein D82868, and c-myc intron binding protein were upregulated. At 20 min of PA the TFs SOX4 and neuronal death factor were upregulated, whereas the TFs c-maf, PEBP major transcription factor, brn-2, homeodomain protein Af004431, and zinc finger transcriptional factor M65008 were downregulated. The biological meaning of our findings is the demonstration of a pathophysiological pattern of TFs including POU, zinc finger, homeodomain, and basic helix-loop helix motifs in PA, proposing pathomechanisms for brain damage from PA, explaining transcriptional changes in general (as, e.g., NF-kappa-B p65, etc.) or in specific terms (as, e.g., neuronal death factor).
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